library(tidyverse) # for data cleaning and plotting
library(lubridate) # for date manipulation
library(openintro) # for the abbr2state() function
library(palmerpenguins)# for Palmer penguin data
library(maps) # for map data
library(ggmap) # for mapping points on maps
library(gplots) # for col2hex() function
library(RColorBrewer) # for color palettes
library(sf) # for working with spatial data
library(leaflet) # for highly customizable mapping
library(carData) # for Minneapolis police stops data
library(ggthemes) # for more themes (including theme_map())
theme_set(theme_minimal())
# Starbucks locations
Starbucks <- read_csv("https://www.macalester.edu/~ajohns24/Data/Starbucks.csv")
starbucks_us_by_state <- Starbucks %>%
filter(Country == "US") %>%
count(`State/Province`) %>%
mutate(state_name = str_to_lower(abbr2state(`State/Province`)))
# Lisa's favorite St. Paul places - example for you to create your own data
favorite_stp_by_lisa <- tibble(
place = c("Home", "Macalester College", "Adams Spanish Immersion",
"Spirit Gymnastics", "Bama & Bapa", "Now Bikes",
"Dance Spectrum", "Pizza Luce", "Brunson's"),
long = c(-93.1405743, -93.1712321, -93.1451796,
-93.1650563, -93.1542883, -93.1696608,
-93.1393172, -93.1524256, -93.0753863),
lat = c(44.950576, 44.9378965, 44.9237914,
44.9654609, 44.9295072, 44.9436813,
44.9399922, 44.9468848, 44.9700727)
)
#COVID-19 data from the New York Times
covid19 <- read_csv("https://raw.githubusercontent.com/nytimes/covid-19-data/master/us-states.csv")
Instructions
Put your name at the top of the document.
For ALL graphs, you should include appropriate labels.
Feel free to change the default theme, which I currently have set to theme_minimal().
Use good coding practice. Read the short sections on good code with pipes and ggplot2. This is part of your grade!
When you are finished with ALL the exercises, uncomment the options at the top so your document looks nicer. Don’t do it before then, or else you might miss some important warnings and messages.
Warm-up exercises from tutorial
These exercises will reiterate what you learned in the “Mapping data with R” tutorial. If you haven’t gone through the tutorial yet, you should do that first.
Starbucks locations (ggmap)
- Add the
Starbucks locations to a world map. Add an aesthetic to the world map that sets the color of the points according to the ownership type. What, if anything, can you deduce from this visualization?
The types of ownerships are very concentrated by country. It appears that the US and Japan have the most Starbucks locations.
world <- get_stamenmap(
bbox = c(left = -180, bottom = -57, right = 179, top = 82.1),
maptype = "terrain",
zoom = 2)
ggmap(world) +
geom_point(data = Starbucks,
aes(x = Longitude, y = Latitude, color = `Ownership Type`),
alpha = .3,
size = .1) +
theme_map() +
labs(title = "Starbucks Location Across the World")

- Construct a new map of Starbucks locations in the Twin Cities metro area (approximately the 5 county metro area).
Twin_Cities <- get_stamenmap(
bbox = c(left = -93.3955, bottom = 44.8004, right = -92.8166, top = 45.0784),
maptype = "watercolor",
zoom = 11)
ggmap(Twin_Cities) +
geom_point(data = Starbucks,
aes(x = Longitude, y = Latitude),
size = .5) +
theme_map() +
labs(title = "Starbucks Location in the Twin Cities")

In the Twin Cities plot, play with the zoom number. What does it do? (just describe what it does - don’t actually include more than one map).
The higher the zoom number the more details are included in the map. When the zoom number is too low the map appears blury and uninformative.
Try a couple different map types (see get_stamenmap() in help and look at maptype). Include a map with one of the other map types.
Twin_Cities <- get_stamenmap(
bbox = c(left = -93.3955, bottom = 44.8004, right = -92.8166, top = 45.0784),
maptype = "watercolor",
zoom = 11)
ggmap(Twin_Cities) +
geom_point(data = Starbucks,
aes(x = Longitude, y = Latitude),
size = .5) +
theme_map() +
labs(title = "Starbucks Location in the Twin Cities")

- Add a point to the map that indicates Macalester College and label it appropriately. There are many ways you can do think, but I think it’s easiest with the
annotate() function (see ggplot2 cheatsheet).
Twin_Cities <- get_stamenmap(
bbox = c(left = -93.3955, bottom = 44.8004, right = -92.8166, top = 45.0784),
maptype = "watercolor",
zoom = 11)
ggmap(Twin_Cities) +
geom_point(data = Starbucks,
aes(x = Longitude, y = Latitude),
size = 1) +
annotate("point", y = 44.9379, x = -93.1691, color = "orange",
size = 10, label = "Macalester" ) +
annotate("text", y = 44.9379, x = -93.1691, color = "navy",
size = 1.7, label = "Macalester" ) +
theme_map() +
labs(title = "Starbucks Location in the Twin Cities")

Choropleth maps with Starbucks data (geom_map())
The example I showed in the tutorial did not account for population of each state in the map. In the code below, a new variable is created, starbucks_per_10000, that gives the number of Starbucks per 10,000 people. It is in the starbucks_with_2018_pop_est dataset.
census_pop_est_2018 <- read_csv("https://www.dropbox.com/s/6txwv3b4ng7pepe/us_census_2018_state_pop_est.csv?dl=1") %>%
separate(state, into = c("dot","state"), extra = "merge") %>%
select(-dot) %>%
mutate(state = str_to_lower(state))
starbucks_with_2018_pop_est <-
starbucks_us_by_state %>%
left_join(census_pop_est_2018,
by = c("state_name" = "state")) %>%
mutate(starbucks_per_10000 = (n/est_pop_2018)*10000)
dplyr review: Look through the code above and describe what each line of code does.
151: Reads in data from url and creates data set called sensus_pop_est_2018 152: breaks up the “.” in front of each State name into its own column 153: selects every variable except the dot variable 154: replaces current state variable with the same names in lower cases
156/157: names a new data set from “starbucks_us_by_state” 158/159: adds the census data set to the starbucks data set by the common variable state name 160: creates a new variable that calculates the proportion of starbucks per 10000 people
- Create a choropleth map that shows the number of Starbucks per 10,000 people on a map of the US. Use a new fill color, add points for all Starbucks in the US (except Hawaii and Alaska), add an informative title for the plot, and include a caption that says who created the plot (you!). Make a conclusion about what you observe.
states_map <- map_data("state")
starbucks_with_2018_pop_est %>%
ggplot() +
geom_map(map = states_map,
aes(map_id = state_name,
fill = starbucks_per_10000 )) +
expand_limits(x = states_map$long, y = states_map$lat) +
geom_point(data = Starbucks
%>% filter(Country == "US", !(`State/Province` %in% c("AK", "HI"))),
aes(x = Longitude, y = Latitude),
color = "red",
size = .1) +
theme_map() +
labs(title = "Density and Dispersion of Starbucks in the US",
subtitle = "by: Pippa Gallagher")

A few of your favorite things (leaflet)
- In this exercise, you are going to create a single map of some of your favorite places! The end result will be one map that satisfies the criteria below.
- Create a data set using the
tibble() function that has 10-15 rows of your favorite places. The columns will be the name of the location, the latitude, the longitude, and a column that indicates if it is in your top 3 favorite locations or not. For an example of how to use tibble(), look at the favorite_stp_by_lisa I created in the data R code chunk at the beginning.
favorite_stp_by_pippa <- tibble(
place = c("Home", "Tam Valley Elementary","Sabrina's","Sol Food",
"Barnes & Noble", "Summit Trail","Sunset",
"Stinson Beach", "Golden Gate Bridge Lookout",
"Burmatown"),
long = c(-122.530700, -122.527777, -122.532238,
-122.535220, -122.517560, -122.568804,
-122.638563, -122.658111, -122.497930, -122.530660 ),
lat = c(37.872520, 37.874140, 37.894744,
37.897800, 37.928020, 37.921195, 37.923904,
37.904385, 37.828207, 37.926990),
fav = c("Yes","No","Yes","No","No","No","Yes","No","No","No")
)
- Create a
leaflet map that uses circles to indicate your favorite places. Label them with the name of the place. Choose the base map you like best. Color your 3 favorite places differently than the ones that are not in your top 3 (HINT: colorFactor()). Add a legend that explains what the colors mean.
pal <- colorFactor(c("#FA8072","#B22222"), favorite_stp_by_pippa$fav)
leaflet(data = favorite_stp_by_pippa) %>%
addProviderTiles(providers$Esri.WorldGrayCanvas) %>%
addCircleMarkers(lng = ~long,
lat = ~lat,
label = ~place,
radius = 5,
fillOpacity = 1,
fillColor = ~pal(fav),
stroke = FALSE) %>%
addLegend("topleft",
pal = pal,
values = ~fav,
opacity = 1) %>%
addPolylines(lng = ~long,
lat = ~lat,
color = col2hex("lightblue"))
Connect all your locations together with a line in a meaningful way (you may need to order them differently in the original data).
If there are other variables you want to add that could enhance your plot, do that now.
Revisiting old datasets
This section will revisit some datasets we have used previously and bring in a mapping component.
Bicycle-Use Patterns
The data come from Washington, DC and cover the last quarter of 2014.
Two data tables are available:
Trips contains records of individual rentals
Stations gives the locations of the bike rental stations
Here is the code to read in the data. We do this a little differently than usualy, which is why it is included here rather than at the top of this file. To avoid repeatedly re-reading the files, start the data import chunk with {r cache = TRUE} rather than the usual {r}. This code reads in the large dataset right away.
data_site <-
"https://www.macalester.edu/~dshuman1/data/112/2014-Q4-Trips-History-Data.rds"
Trips <- readRDS(gzcon(url(data_site)))
Stations<-read_csv("http://www.macalester.edu/~dshuman1/data/112/DC-Stations.csv")
- Use the latitude and longitude variables in
Stations to make a visualization of the total number of departures from each station in the Trips data. Use either color or size to show the variation in number of departures. This time, plot the points on top of a map. Use any of the mapping tools you’d like.
DC_map <- get_stamenmap(
bbox = c(left = -77.3039, bottom = 38.7332, right = -76.7251, top = 39.0539),
maptype = "terrain",
zoom = 11)
trips_map <- Trips %>%
left_join(Stations, by = c( "sstation" = "name")) %>%
group_by(lat,long) %>%
summarise(departures = n())
ggmap(DC_map) +
geom_point(data = trips_map,
aes(y=lat, x = long, color = departures),
size = 0.5) +
theme_map()

- Only 14.4% of the trips in our data are carried out by casual users. Create a plot that shows which area(s) have stations with a much higher percentage of departures by casual users. What patterns do you notice? Also plot this on top of a map. I think it will be more clear what the patterns are.
The center or downtown of DC have a higher proportion of casual users and as you get further from the center, the density of bike stations decreases.
trips_map <- Trips %>%
left_join(Stations, by = c( "sstation" = "name")) %>%
group_by(lat, long) %>%
summarise(prop_departures = sum(client == "Casual")/n())
DC_map <- get_stamenmap(
bbox = c(left = -77.3039, bottom = 38.7332, right = -76.7251, top = 39.0539),
maptype = "terrain",
zoom = 11)
ggmap(DC_map) +
geom_point(data = trips_map,
aes(y = lat, x = long, color = prop_departures),
size = 0.5) +
labs(title = "Map of the Stations' Casual vs Registered Proportions",
x = "",
y = "")

COVID-19 data
The following exercises will use the COVID-19 data from the NYT.
- Create a map that colors the states by the most recent cumulative number of COVID-19 cases (remember, these data report cumulative numbers so you don’t need to compute that). Describe what you see. What is the problem with this map?
This map does not account for the differences in populations between states. California is shown as having the most COVID019 cases, which is accurate, but misleading because it is also the most populated state.
states_map <- map_data("state")
covid19 %>%
mutate(state = str_to_lower(state)) %>%
group_by(state) %>%
summarise(cases = max(cases)) %>%
ggplot() +
geom_map(map = states_map,
aes(map_id = state,
fill = cases)) +
expand_limits(x = states_map$long, y = states_map$lat) +
theme_map() +
labs(title = "Cumulative Number of COVID-19 Cases in US")

- Now add the population of each state to the dataset and color the states by most recent cumulative cases/10,000 people. See the code for doing this with the Starbucks data. You will need to make some modifications.
states_map <- map_data("state")
census_pop_est_2018 <- read_csv("https://www.dropbox.com/s/6txwv3b4ng7pepe/us_census_2018_state_pop_est.csv?dl=1") %>%
separate(state, into = c("dot","state"), extra = "merge") %>%
select(-dot) %>%
mutate(state = str_to_lower(state))
covid_with_2018_pop_est <-
covid19 %>%
mutate(state = str_to_lower(state)) %>%
left_join(census_pop_est_2018,
by = c("state" = "state")) %>%
group_by(state) %>%
mutate(cases = max(cases),
covid_per_10000 = (cases/est_pop_2018)*10000)
covid_with_2018_pop_est %>%
ggplot() +
geom_map(map = states_map,
aes(map_id = state,
fill = covid_per_10000)) +
expand_limits(x = states_map$long, y = states_map$lat) +
theme_map() +
labs(title = "Cumulative Number of COVID-19 Cases in US per 10,000 People",
fill = "")

- CHALLENGE Choose 4 dates spread over the time period of the data and create the same map as in exercise 12 for each of the dates. Display the four graphs together using faceting. What do you notice?
states_map <- map_data("state")
census_pop_est_2018 <- read_csv("https://www.dropbox.com/s/6txwv3b4ng7pepe/us_census_2018_state_pop_est.csv?dl=1") %>%
separate(state, into = c("dot","state"), extra = "merge") %>%
select(-dot) %>%
mutate(state = str_to_lower(state))
covid_with_2018_pop_est <-
covid19 %>%
filter(date %in% c("2020-03-30","2020-08-30","2020-12-30","2021-02-15")) %>%
mutate(state = str_to_lower(state)) %>%
left_join(census_pop_est_2018,
by = c("state" = "state")) %>%
group_by(state) %>%
mutate(cases = max(cases),
covid_per_10000 = (cases/est_pop_2018)*10000)
covid_with_2018_pop_est %>%
ggplot() +
geom_map(map = states_map,
aes(map_id = state,
fill = covid_per_10000)) +
expand_limits(x = states_map$long, y = states_map$lat) +
theme_map() +
facet_wrap(vars(date)) +
labs(title = "Cumulative Number of COVID-19 Cases in US per 10,000 People",
fill = "")
## Error: Faceting variables must have at least one value

Minneapolis police stops
These exercises use the datasets MplsStops and MplsDemo from the carData library. Search for them in Help to find out more information.
- Use the
MplsStops dataset to find out how many stops there were for each neighborhood and the proportion of stops that were for a suspicious vehicle or person. Sort the results from most to least number of stops. Save this as a dataset called mpls_suspicious and display the table.
mpls_suspicious <-
MplsStops %>%
group_by(neighborhood) %>%
mutate(num_stops = n()) %>%
group_by(neighborhood, problem) %>%
mutate(num_sus = n(),
proportion = num_sus/num_stops) %>%
arrange(num_stops)
- Use a
leaflet map and the MplsStops dataset to display each of the stops on a map as a small point. Color the points differently depending on whether they were for suspicious vehicle/person or a traffic stop (the problem variable). HINTS: use addCircleMarkers, set stroke = FAlSE, use colorFactor() to create a palette.
pal <- colorFactor(c("#ADD8E6","#9370DB"),
domain = MplsStops$problem)
leaflet(data = MplsStops) %>%
addProviderTiles(providers$Esri.WorldGrayCanvas) %>%
addCircleMarkers(lng = ~long,
lat = ~lat,
fillColor = ~pal(problem),
radius = 2,
stroke = FALSE) %>%
addLegend("topleft",
pal = pal,
values = ~problem,
opacity = 1)
- Save the folder from moodle called Minneapolis_Neighborhoods into your project/repository folder for this assignment. Make sure the folder is called Minneapolis_Neighborhoods. Use the code below to read in the data and make sure to delete the
eval=FALSE. Although it looks like it only links to the .sph file, you need the entire folder of files to create the mpls_nbhd data set. These data contain information about the geometries of the Minneapolis neighborhoods. Using the mpls_nbhd dataset as the base file, join the mpls_suspicious and MplsDemo datasets to it by neighborhood (careful, they are named different things in the different files). Call this new dataset mpls_all.
mpls_nbhd <- st_read("Minneapolis_Neighborhoods/Minneapolis_Neighborhoods.shp", quiet = TRUE)
mpls_all <-
mpls_nbhd %>%
left_join(MplsDemo, by = c("BDNAME" = "neighborhood")) %>%
left_join(mpls_suspicious, by = c("BDNAME" = "neighborhood"))
## Error in left_join(., MplsDemo, by = c(BDNAME = "neighborhood")): object 'mpls_nbhd' not found
mpls_all
## Error in eval(expr, envir, enclos): object 'mpls_all' not found
- Use
leaflet to create a map from the mpls_all data that colors the neighborhoods by prop_suspicious. Display the neighborhood name as you scroll over it. Describe what you observe in the map.
leaflet(data = mpls_all) %>%
addProviderTiles(providers$Esri.WorldImagery) %>%
addTiles() %>%
addPolygons()
## Error in structure(list(options = options), leafletData = data): object 'mpls_all' not found
- Use
leaflet to create a map of your own choosing. Come up with a question you want to try to answer and use the map to help answer that question. Describe what your map shows.
Question: What is the distribution of stops that are male vs female?
This map shows clearly how much more frequently men are pulled over and stopped. The yellow outweighs the little purple that shows.
pal <- colorFactor(c("#4B0082","#FFFF00","#800000"),
domain = MplsStops$gender)
leaflet(data = MplsStops) %>%
addProviderTiles(providers$Esri.WorldGrayCanvas) %>%
addCircleMarkers(lng = ~long,
lat = ~lat,
fillColor = ~pal(gender),
fillOpacity = 1,
radius = 2,
stroke = FALSE) %>%
addLegend("topleft",
pal = pal,
values = ~gender,
opacity = 1)
GitHub link
- Below, provide a link to your GitHub page with this set of Weekly Exercises. Specifically, if the name of the file is 04_exercises.Rmd, provide a link to the 04_exercises.md file, which is the one that will be most readable on GitHub.
DID YOU REMEMBER TO UNCOMMENT THE OPTIONS AT THE TOP?
---
title: 'Weekly Exercises #4'
author: "Pippa Gallagher"
output: 
  html_document:
    keep_md: TRUE
    toc: TRUE
    toc_float: TRUE
    df_print: paged
    code_download: true
---


```{r setup, include=FALSE}
knitr::opts_chunk$set(echo = TRUE, error=TRUE, message=FALSE, warning=FALSE)
```

```{r libraries}
library(tidyverse)     # for data cleaning and plotting
library(lubridate)     # for date manipulation
library(openintro)     # for the abbr2state() function
library(palmerpenguins)# for Palmer penguin data
library(maps)          # for map data
library(ggmap)         # for mapping points on maps
library(gplots)        # for col2hex() function
library(RColorBrewer)  # for color palettes
library(sf)            # for working with spatial data
library(leaflet)       # for highly customizable mapping
library(carData)       # for Minneapolis police stops data
library(ggthemes)      # for more themes (including theme_map())
theme_set(theme_minimal())
```

```{r data}
# Starbucks locations
Starbucks <- read_csv("https://www.macalester.edu/~ajohns24/Data/Starbucks.csv")

starbucks_us_by_state <- Starbucks %>% 
  filter(Country == "US") %>% 
  count(`State/Province`) %>% 
  mutate(state_name = str_to_lower(abbr2state(`State/Province`))) 

# Lisa's favorite St. Paul places - example for you to create your own data
favorite_stp_by_lisa <- tibble(
  place = c("Home", "Macalester College", "Adams Spanish Immersion", 
            "Spirit Gymnastics", "Bama & Bapa", "Now Bikes",
            "Dance Spectrum", "Pizza Luce", "Brunson's"),
  long = c(-93.1405743, -93.1712321, -93.1451796, 
           -93.1650563, -93.1542883, -93.1696608, 
           -93.1393172, -93.1524256, -93.0753863),
  lat = c(44.950576, 44.9378965, 44.9237914,
          44.9654609, 44.9295072, 44.9436813, 
          44.9399922, 44.9468848, 44.9700727)
  )

#COVID-19 data from the New York Times
covid19 <- read_csv("https://raw.githubusercontent.com/nytimes/covid-19-data/master/us-states.csv")

```


## Instructions

* Put your name at the top of the document. 

* **For ALL graphs, you should include appropriate labels.** 

* Feel free to change the default theme, which I currently have set to `theme_minimal()`. 

* Use good coding practice. Read the short sections on good code with [pipes](https://style.tidyverse.org/pipes.html) and [ggplot2](https://style.tidyverse.org/ggplot2.html). **This is part of your grade!**

* When you are finished with ALL the exercises, uncomment the options at the top so your document looks nicer. Don't do it before then, or else you might miss some important warnings and messages.


## Warm-up exercises from tutorial

These exercises will reiterate what you learned in the "Mapping data with R" tutorial. If you haven't gone through the tutorial yet, you should do that first.

### Starbucks locations (`ggmap`)

  1. Add the `Starbucks` locations to a world map. Add an aesthetic to the world map that sets the color of the points according to the ownership type. What, if anything, can you deduce from this visualization?  
  
  The types of ownerships are very concentrated by country. It appears that the US and Japan have the most Starbucks locations. 
  
  
```{r}
world <- get_stamenmap(
    bbox = c(left = -180, bottom = -57, right = 179, top = 82.1), 
    maptype = "terrain",
    zoom = 2)
ggmap(world) + 
  geom_point(data = Starbucks, 
             aes(x = Longitude, y = Latitude, color = `Ownership Type`),
             alpha = .3, 
             size = .1) +
  theme_map() +
  labs(title = "Starbucks Location Across the World")
```
  

  2. Construct a new map of Starbucks locations in the Twin Cities metro area (approximately the 5 county metro area).  
  
```{r}
Twin_Cities <- get_stamenmap(
  bbox = c(left = -93.3955, bottom = 44.8004, right = -92.8166, top = 45.0784), 
    maptype = "watercolor",
    zoom = 11)
ggmap(Twin_Cities) + 
  geom_point(data = Starbucks, 
             aes(x = Longitude, y = Latitude),
             size = .5) +
  theme_map() +
   labs(title = "Starbucks Location in the Twin Cities")
```
  

  3. In the Twin Cities plot, play with the zoom number. What does it do?  (just describe what it does - don't actually include more than one map).  
  The higher the zoom number the more details are included in the map. When the zoom number is too low the map appears blury and uninformative. 

  4. Try a couple different map types (see `get_stamenmap()` in help and look at `maptype`). Include a map with one of the other map types.  
  
```{r}
Twin_Cities <- get_stamenmap(
  bbox = c(left = -93.3955, bottom = 44.8004, right = -92.8166, top = 45.0784), 
    maptype = "watercolor",
    zoom = 11)
ggmap(Twin_Cities) + 
  geom_point(data = Starbucks, 
             aes(x = Longitude, y = Latitude),
             size = .5) +
  theme_map() +
   labs(title = "Starbucks Location in the Twin Cities")
```

  5. Add a point to the map that indicates Macalester College and label it appropriately. There are many ways you can do think, but I think it's easiest with the `annotate()` function (see `ggplot2` cheatsheet).
  
```{r}
Twin_Cities <- get_stamenmap(
  bbox = c(left = -93.3955, bottom = 44.8004, right = -92.8166, top = 45.0784), 
    maptype = "watercolor",
    zoom = 11)
ggmap(Twin_Cities) + 
  geom_point(data = Starbucks, 
             aes(x = Longitude, y = Latitude),
             size = 1) +
  annotate("point", y = 44.9379, x = -93.1691, color = "orange", 
           size = 10, label = "Macalester" ) + 
  annotate("text", y = 44.9379, x = -93.1691, color = "navy", 
           size = 1.7, label = "Macalester" ) + 
  theme_map() +
  labs(title = "Starbucks Location in the Twin Cities")
```

### Choropleth maps with Starbucks data (`geom_map()`)

The example I showed in the tutorial did not account for population of each state in the map. In the code below, a new variable is created, `starbucks_per_10000`, that gives the number of Starbucks per 10,000 people. It is in the `starbucks_with_2018_pop_est` dataset.

```{r}
census_pop_est_2018 <- read_csv("https://www.dropbox.com/s/6txwv3b4ng7pepe/us_census_2018_state_pop_est.csv?dl=1") %>% 
  separate(state, into = c("dot","state"), extra = "merge") %>% 
  select(-dot) %>% 
  mutate(state = str_to_lower(state))

starbucks_with_2018_pop_est <-
  starbucks_us_by_state %>% 
  left_join(census_pop_est_2018,
            by = c("state_name" = "state")) %>% 
  mutate(starbucks_per_10000 = (n/est_pop_2018)*10000)
```

  6. **`dplyr` review**: Look through the code above and describe what each line of code does.
  
151: Reads in data from url and creates data set called sensus_pop_est_2018
152: breaks up the "." in front of each State name into its own column 
153: selects every variable except the dot variable 
154: replaces current state variable with the same names in lower cases 

156/157: names a new data set from "starbucks_us_by_state"
158/159: adds the census data set to the starbucks data set by the common variable state name
160: creates a new variable that calculates the proportion of starbucks per 10000 people


  7. Create a choropleth map that shows the number of Starbucks per 10,000 people on a map of the US. Use a new fill color, add points for all Starbucks in the US (except Hawaii and Alaska), add an informative title for the plot, and include a caption that says who created the plot (you!). Make a conclusion about what you observe.
  
  
```{r}
states_map <- map_data("state")
starbucks_with_2018_pop_est %>% 
  ggplot() +
  geom_map(map = states_map,
           aes(map_id = state_name,
               fill = starbucks_per_10000 )) +
  expand_limits(x = states_map$long, y = states_map$lat) + 
  geom_point(data = Starbucks
                    %>% filter(Country == "US", !(`State/Province` %in% c("AK", "HI"))), 
             aes(x = Longitude, y = Latitude),
             color = "red",
             size = .1) +
  theme_map() +
  labs(title = "Density and Dispersion of Starbucks in the US",
       subtitle = "by: Pippa Gallagher")
```
  

### A few of your favorite things (`leaflet`)

  8. In this exercise, you are going to create a single map of some of your favorite places! The end result will be one map that satisfies the criteria below. 

  * Create a data set using the `tibble()` function that has 10-15 rows of your favorite places. The columns will be the name of the location, the latitude, the longitude, and a column that indicates if it is in your top 3 favorite locations or not. For an example of how to use `tibble()`, look at the `favorite_stp_by_lisa` I created in the data R code chunk at the beginning.  
  
```{r}
favorite_stp_by_pippa <- tibble(
  place = c("Home", "Tam Valley Elementary","Sabrina's","Sol Food",  
            "Barnes & Noble", "Summit Trail","Sunset", 
            "Stinson Beach", "Golden Gate Bridge Lookout", 
            "Burmatown"),
  long = c(-122.530700, -122.527777, -122.532238, 
           -122.535220, -122.517560, -122.568804, 
           -122.638563, -122.658111, -122.497930, -122.530660 ),
  lat = c(37.872520,  37.874140, 37.894744, 
          37.897800, 37.928020, 37.921195, 37.923904,
          37.904385, 37.828207, 37.926990),
  fav = c("Yes","No","Yes","No","No","No","Yes","No","No","No")
  )
```
  

  * Create a `leaflet` map that uses circles to indicate your favorite places. Label them with the name of the place. Choose the base map you like best. Color your 3 favorite places differently than the ones that are not in your top 3 (HINT: `colorFactor()`). Add a legend that explains what the colors mean.  
  
```{r}
pal <- colorFactor(c("#FA8072","#B22222"), favorite_stp_by_pippa$fav)


leaflet(data = favorite_stp_by_pippa) %>% 
  addProviderTiles(providers$Esri.WorldGrayCanvas) %>% 
  addCircleMarkers(lng = ~long, 
                  lat = ~lat,
                  label = ~place,
                  radius = 5,
                  fillOpacity = 1,
                  fillColor = ~pal(fav),
                  stroke = FALSE) %>% 
   addLegend("topleft",
            pal = pal,
            values = ~fav,
            opacity = 1) %>% 
  addPolylines(lng = ~long, 
               lat = ~lat, 
               color = col2hex("lightblue"))
  
```
  
  
  * Connect all your locations together with a line in a meaningful way (you may need to order them differently in the original data).  
  
  * If there are other variables you want to add that could enhance your plot, do that now.  
  
## Revisiting old datasets

This section will revisit some datasets we have used previously and bring in a mapping component. 

### Bicycle-Use Patterns

The data come from Washington, DC and cover the last quarter of 2014.

Two data tables are available:

- `Trips` contains records of individual rentals
- `Stations` gives the locations of the bike rental stations

Here is the code to read in the data. We do this a little differently than usualy, which is why it is included here rather than at the top of this file. To avoid repeatedly re-reading the files, start the data import chunk with `{r cache = TRUE}` rather than the usual `{r}`. This code reads in the large dataset right away.

```{r cache=TRUE}
data_site <- 
  "https://www.macalester.edu/~dshuman1/data/112/2014-Q4-Trips-History-Data.rds" 
Trips <- readRDS(gzcon(url(data_site)))
Stations<-read_csv("http://www.macalester.edu/~dshuman1/data/112/DC-Stations.csv")
```

  9. Use the latitude and longitude variables in `Stations` to make a visualization of the total number of departures from each station in the `Trips` data. Use either color or size to show the variation in number of departures. This time, plot the points on top of a map. Use any of the mapping tools you'd like.
  
```{r}
DC_map <- get_stamenmap(
    bbox = c(left = -77.3039, bottom = 38.7332, right = -76.7251, top = 39.0539), 
    maptype = "terrain",
    zoom = 11)

trips_map <- Trips %>% 
  left_join(Stations, by = c( "sstation" = "name")) %>% 
  group_by(lat,long) %>% 
  summarise(departures = n()) 

ggmap(DC_map) +
  geom_point(data = trips_map,
    aes(y=lat, x = long, color = departures),
    size = 0.5) +
 theme_map()
```
  
  10. Only 14.4% of the trips in our data are carried out by casual users. Create a plot that shows which area(s) have stations with a much higher percentage of departures by casual users. What patterns do you notice? Also plot this on top of a map. I think it will be more clear what the patterns are.
  
  The center or downtown of DC have a higher proportion of casual users and as you get further from the center, the density of bike stations decreases. 
  
```{r}
trips_map <- Trips %>% 
  left_join(Stations, by = c( "sstation" = "name")) %>% 
  group_by(lat, long) %>%
  summarise(prop_departures = sum(client == "Casual")/n()) 

DC_map <- get_stamenmap(
    bbox = c(left = -77.3039, bottom = 38.7332, right = -76.7251, top = 39.0539), 
    maptype = "terrain",
    zoom = 11)

  ggmap(DC_map) +
  geom_point(data = trips_map,
    aes(y = lat, x = long, color = prop_departures),
    size = 0.5) +
  labs(title = "Map of the Stations' Casual vs Registered Proportions",
       x = "",
       y = "")
  
```
  
### COVID-19 data


The following exercises will use the COVID-19 data from the NYT.

  11. Create a map that colors the states by the most recent cumulative number of COVID-19 cases (remember, these data report cumulative numbers so you don't need to compute that). Describe what you see. What is the problem with this map?
  
  This map does not account for the differences in populations between states. California is shown as having the most COVID019 cases, which is accurate, but misleading because it is also the most populated state.
  
```{r}
states_map <- map_data("state")

covid19 %>% 
  mutate(state = str_to_lower(state)) %>% 
  group_by(state) %>% 
  summarise(cases = max(cases)) %>% 
  ggplot() +
  geom_map(map = states_map,
           aes(map_id = state,
               fill = cases)) +
  expand_limits(x = states_map$long, y = states_map$lat) +
  theme_map() +
  labs(title = "Cumulative Number of COVID-19 Cases in US")
```
  
  
  12. Now add the population of each state to the dataset and color the states by most recent cumulative cases/10,000 people. See the code for doing this with the Starbucks data. You will need to make some modifications. 
  
```{r}
states_map <- map_data("state")

census_pop_est_2018 <- read_csv("https://www.dropbox.com/s/6txwv3b4ng7pepe/us_census_2018_state_pop_est.csv?dl=1") %>% 
  separate(state, into = c("dot","state"), extra = "merge") %>% 
  select(-dot) %>% 
  mutate(state = str_to_lower(state))

covid_with_2018_pop_est <-
  covid19 %>% 
  mutate(state = str_to_lower(state)) %>% 
  left_join(census_pop_est_2018,
            by = c("state" = "state")) %>% 
  group_by(state) %>% 
  mutate(cases = max(cases),
            covid_per_10000 = (cases/est_pop_2018)*10000)

covid_with_2018_pop_est %>% 
  ggplot() +
  geom_map(map = states_map,
           aes(map_id = state,
               fill = covid_per_10000)) +
  expand_limits(x = states_map$long, y = states_map$lat) +
  theme_map() +
  labs(title = "Cumulative Number of COVID-19 Cases in US per 10,000 People",
       fill = "")
```
  
  13. **CHALLENGE** Choose 4 dates spread over the time period of the data and create the same map as in exercise 12 for each of the dates. Display the four graphs together using faceting. What do you notice?
  
```{r}
states_map <- map_data("state")

census_pop_est_2018 <- read_csv("https://www.dropbox.com/s/6txwv3b4ng7pepe/us_census_2018_state_pop_est.csv?dl=1") %>% 
  separate(state, into = c("dot","state"), extra = "merge") %>% 
  select(-dot) %>% 
  mutate(state = str_to_lower(state))

covid_with_2018_pop_est <-
  covid19 %>% 
  filter(date %in% c("2020-03-30","2020-08-30","2020-12-30","2021-02-15")) %>% 
  mutate(state = str_to_lower(state)) %>% 
  left_join(census_pop_est_2018,
            by = c("state" = "state")) %>% 
  group_by(state) %>% 
  mutate(cases = max(cases),
            covid_per_10000 = (cases/est_pop_2018)*10000)

covid_with_2018_pop_est %>% 
  ggplot() +
  geom_map(map = states_map,
           aes(map_id = state,
               fill = covid_per_10000)) +
  expand_limits(x = states_map$long, y = states_map$lat) +
  theme_map() +
  facet_wrap(vars(date)) + 
  labs(title = "Cumulative Number of COVID-19 Cases in US per 10,000 People",
       fill = "")
```
  
  
## Minneapolis police stops

These exercises use the datasets `MplsStops` and `MplsDemo` from the `carData` library. Search for them in Help to find out more information.

  14. Use the `MplsStops` dataset to find out how many stops there were for each neighborhood and the proportion of stops that were for a suspicious vehicle or person. Sort the results from most to least number of stops. Save this as a dataset called `mpls_suspicious` and display the table.  
  
```{r}
mpls_suspicious <-
  MplsStops %>% 
  group_by(neighborhood) %>% 
  mutate(num_stops = n()) %>% 
  group_by(neighborhood, problem) %>% 
  mutate(num_sus = n(),
         proportion = num_sus/num_stops) %>% 
  arrange(num_stops)
```
  
  
  15. Use a `leaflet` map and the `MplsStops` dataset to display each of the stops on a map as a small point. Color the points differently depending on whether they were for suspicious vehicle/person or a traffic stop (the `problem` variable). HINTS: use `addCircleMarkers`, set `stroke = FAlSE`, use `colorFactor()` to create a palette. 
  
```{r}
pal <- colorFactor(c("#ADD8E6","#9370DB"), 
                     domain = MplsStops$problem) 

leaflet(data = MplsStops) %>% 
  addProviderTiles(providers$Esri.WorldGrayCanvas) %>% 
  addCircleMarkers(lng = ~long, 
                  lat = ~lat,
                  fillColor = ~pal(problem),
                  radius = 2,
                  stroke = FALSE) %>% 
     addLegend("topleft",
            pal = pal,
            values = ~problem,
            opacity = 1)
```
  
  16. Save the folder from moodle called Minneapolis_Neighborhoods into your project/repository folder for this assignment. Make sure the folder is called Minneapolis_Neighborhoods. Use the code below to read in the data and make sure to **delete the `eval=FALSE`**. Although it looks like it only links to the .sph file, you need the entire folder of files to create the `mpls_nbhd` data set. These data contain information about the geometries of the Minneapolis neighborhoods. Using the `mpls_nbhd` dataset as the base file, join the `mpls_suspicious` and `MplsDemo` datasets to it by neighborhood (careful, they are named different things in the different files). Call this new dataset `mpls_all`.

```{r, eval=FALSE}
mpls_nbhd <- st_read("Minneapolis_Neighborhoods/Minneapolis_Neighborhoods.shp", quiet = TRUE)
```


```{r}
mpls_all <-
  mpls_nbhd %>% 
  left_join(MplsDemo, by = c("BDNAME" = "neighborhood")) %>% 
  left_join(mpls_suspicious, by = c("BDNAME" = "neighborhood")) 

mpls_all
```

  17. Use `leaflet` to create a map from the `mpls_all` data  that colors the neighborhoods by `prop_suspicious`. Display the neighborhood name as you scroll over it. Describe what you observe in the map.
  
```{r}
leaflet(data = mpls_all) %>% 
  addProviderTiles(providers$Esri.WorldImagery) %>% 
  addTiles() %>% 
  addPolygons()
  
```

  
  18. Use `leaflet` to create a map of your own choosing. Come up with a question you want to try to answer and use the map to help answer that question. Describe what your map shows. 
  
  Question: What is the distribution of stops that are male vs female? 
  
  This map shows clearly how much more frequently men are pulled over and stopped. The yellow outweighs the little purple that shows. 
   
```{r}
pal <- colorFactor(c("#4B0082","#FFFF00","#800000"), 
                     domain = MplsStops$gender) 

leaflet(data = MplsStops) %>% 
  addProviderTiles(providers$Esri.WorldGrayCanvas) %>% 
  addCircleMarkers(lng = ~long, 
                  lat = ~lat,
                  fillColor = ~pal(gender),
                  fillOpacity = 1,
                  radius = 2,
                  stroke = FALSE) %>% 
     addLegend("topleft",
            pal = pal,
            values = ~gender,
            opacity = 1)

```
  
  
  
## GitHub link

  19. Below, provide a link to your GitHub page with this set of Weekly Exercises. Specifically, if the name of the file is 04_exercises.Rmd, provide a link to the 04_exercises.md file, which is the one that will be most readable on GitHub.


**DID YOU REMEMBER TO UNCOMMENT THE OPTIONS AT THE TOP?**
